Salazar Joelle K, George Josephina, Fay Megan L, Stewart Diana S, Ingram David T
Division of Food Processing Science and Technology, U.S. Food and Drug Administration, Bedford Park, IL, United States.
Department of Food Science and Nutrition, Institute for Food Safety and Health, Illinois Institute of Technology, Bedford Park, IL, United States.
Front Microbiol. 2024 Aug 5;15:1406971. doi: 10.3389/fmicb.2024.1406971. eCollection 2024.
Specialty mushrooms have been implicated in foodborne illness outbreaks in the U.S. in recent years. These mushrooms are available to consumers in both their fresh and dried states. Dehydrating mushrooms is a convenient way to increase shelf life. The dehydration process results in a lowered water activity (a) of the commodity, creating an environment where both spoilage and pathogenic bacteria cannot proliferate. Prior to food preparation and consumption, these mushrooms are typically rehydrated and possibly stored for later use which could lead to increased levels of pathogens. This study examined the survival and growth of and on dehydrated enoki and wood ear mushrooms during rehydration and subsequent storage. Mushrooms were heat dehydrated, inoculated at 3 log CFU/g, and rehydrated at either 5 or 25°C for 2 h. Rehydrated mushrooms were stored at 5, 10, or 25°C for up to 14 d. and survived on enoki and wood ear mushroom types during rehydration at 5 and 25°C, with populations often <2.39 log CFU/g. During subsequent storage, no growth was observed on wood ear mushrooms, regardless of the rehydration or storage temperature, with populations remaining <2.39 log CFU/g for both pathogens. When stored at 5°C, no growth was observed for either pathogen on enoki mushrooms. During storage at 10 and 25°C, pathogen growth rates and populations after 14 d were generally significantly higher on the enoki mushrooms rehydrated at 25°C; the highest growth rate (3.56 ± 0.75 log CFU/g/d) and population (9.48 ± 0.62 log CFU/g) after 14 d for either pathogen was observed by at 25°C storage temperature. Results indicate a marked difference in pathogen survival and proliferation on the two specialty mushrooms examined in this study and highlight the need for individual product assessments. Data can be used to assist in informing guidelines for time and temperature control for the safety of rehydrated mushrooms.
近年来,特色蘑菇在美国引发了多起食源性疾病暴发事件。这些蘑菇有新鲜的和干制的两种形式供消费者购买。将蘑菇脱水是延长保质期的便捷方法。脱水过程会降低产品的水分活度(a),营造出一个腐败菌和致病菌都无法繁殖的环境。在进行食品制备和食用之前,这些蘑菇通常要进行复水,并且可能会储存起来以备后用,而这可能会导致病原体数量增加。本研究考察了脱水金针菇和木耳在复水及后续储存过程中两种病原体的存活和生长情况。蘑菇经加热脱水后,接种量为3 log CFU/g,并在5或25°C下复水2小时。复水后的蘑菇在5、10或25°C下储存长达14天。两种病原体在5和25°C复水的金针菇和木耳上均能存活,菌量通常<2.39 log CFU/g。在后续储存过程中,无论复水温度或储存温度如何,木耳上均未观察到生长,两种病原体的菌量均保持<2.39 log CFU/g。在5°C储存时,金针菇上两种病原体均未观察到生长。在10和25°C储存期间,25°C复水的金针菇上病原体的生长速率和14天后的菌量通常显著更高;在25°C储存温度下,两种病原体在14天后的最高生长速率(3.56±0.75 log CFU/g/d)和菌量(9.48±0.62 log CFU/g)均出现在25°C复水的金针菇上。结果表明,本研究中所检测的两种特色蘑菇在病原体存活和增殖方面存在显著差异,并突出了对单个产品进行评估的必要性。这些数据可用于协助制定复水蘑菇安全的时间和温度控制指南。
